Electric fish-repelling device

Patent 4593648 Issued on June 10, 1986. Estimated Expiration Date:

April 23, 2004. Estimated Expiration Date is calculated based on simple USPTO term provisions. It does not account for terminal disclaimers, term adjustments, failure to pay maintenance fees, or other factors which might affect the term of a patent.

Abstract Claims Description Full Text

Patent References

1515547

1974444

2010601

2233045

3634222

Inventor

Marzluf, Werner

Assignee

Maschinenfabrik Hellmut Geiger GmbH & Co. KG

Application

No. 06/602725 filed on 04/23/1984

US Classes:

119/220Electric type

Examiners

Primary: Chamblee, Hugh R.

Attorney, Agent or Firm

Wenderoth, Lind & Ponack

International Classes

A01K 79/02 (20060101)
A01K 79/00 (20060101)
A01M 29/00 (20060101)

Description

BACKGROUND OF THE INVENTION

The invention relates to an electric fish scaring or repelling device, intended particularly for water inlet and extraction structures, in which several main electrodes are positioned below the surface of the water and connected to a voltagesupply unit which produces a pulsed voltage pattern.

Fish-scaring devices are used as a measure to conserve fish stocks and to avoid interruptions in the operation of and the risk of damage to items of equipment in power stations. These devices are installed in the vicinity of water inlet andextraction structures and prevent corresponding damage to the environment as a result of the destruction of organisms living in the water, particularly fish. Electric fish-scaring devices already in use contain a number of main and counter-electrodeswhich are positioned at appropriate intervals, and which are connected to the terminals of a d.c. or a.c. voltage supply unit. This voltage supply unit generates series of positive and negative pulses which are supplied to the main andcounter-electrodes. Known fish scaring devices of the type described above are kept in operation with practically no further checks after preliminary tests and the comprehensive measurements and adjustments of the device carried out duringcommissioning. As a result a change and particularly a reduction in the scaring effect are noticed only when considerable damage has occurred.

Such changes in the scaring effect can occur as a result of fluctuations in the electrode characteristics, which may, for example, take the form of an accelerating increase in the surface resistance or of changing characteristic values of watercomposition, particularly the conductivity of the water, which determines the extent of the field, and the distribution of the organisms.

SUMMARY OF THE INVENTION

The invention is based on the need to develop an electric fish scaring or repelling device that will permit continuous monitoring of its effectiveness and, where necessary, appropriate readjustment of its current density or field strengthcomponents. The solution to this problem lies in the fact that at least one simulator electrode is positioned at a predetermined distance in front of the main electrodes. This enables the electrical current density or field strength to be monitored inrealistic environmental conditions.

As the electrical field strength is essentially determined by the distribution of the dielectrics or conductive liquids, it appears appropriate to make the simulator electrode of such a material and in such a form that in its dielectric behaviourand conductivity behaviour and/or its geometry it corresponds to the body of a fish. To conduct the measured values, metallic measurement sensors can usefully be embedded in the simulator electrode or applied as a coating on specific areas of itssurface. Because of the additional dependence of the field strength distribution on the distribution of organisms in the water, it may in certain circumstances be desirable to position several simulator electrodes in front of the main electrodes and inconsequence to monitor, for example, a larger inlet area for a power station condenser.

Sufficient current density must be available in order to provide an adequate scaring effect. If this density is not achieved, the device will operate with only a very poor degree of effectiveness.

The device is preferably constructed in such a way that counter-electrodes are positioned at a certain distance from the main electrodes, preferably downstream behind the main electrodes. These counter-electrodes can in certain circumstances bereplaced by parts of the structure, e.g. by metal grating bars.

When positioning simulator electrodes of this type, the current density or the electrical field strength is measured in the vicinity of the simulator electrode and used as the control signal for the voltage supply unit so that an electricalcurrent density sufficient to ensure the effectiveness of the device is maintained at the simulator electrode independently of variations in the electrode characteristics, the characteristic values of the water and the distribution of organisms. Themeasured values obtained can be processed by a microprocessor which allows direct display of the current density or field strength for the selected measurement points in the monitored area and can also be used for the automatic regulation of the voltagesupply unit.

Application of the invention enables fish-scaring devices to be monitored, and the voltage supply can be regulated in such a way that economical operation is possible with the optimum scaring effect.

BRIEF DESCRIPTION OF THE DRAWING

Other objects, features and advantages of the invention will be apparent from the following description, with reference to the accompanying drawing, wherein the single FIGURE is a schematic view of an example of the device of the invention.

DETAILED DESCRIPTION OF THE INVENTION

In front of a water inlet 2 protected by a grating 1 there is a row of main electrodes 3, which are supplied by a voltage unit 4 with a pulsed d.c. voltage of an appropriate stength and pulse duration. This pulsed voltage passes between themain electrodes 3 and the counter-electrodes 7 located behind the grating 1, which are also connected to the voltage unit.

In front of the main electrodes 3 there is a simulator electrode 5, which consists of a streamlined body imitating the dielectric behaviour and conductivity behaviour of the body of a fish and a measurement sensor 6, which is used to measure theelectric field strength. The measurement sensor 6 can be formed with one or several poles and, if appropriate, also consist of several measurement points or plates arranged at a certain distance from the simulator electrode 5. In certain circumstancesthe measurement sensor 6 can also be connected to a suitably conductive surface coating. To determine the conductivity of the water, a conductivity measurement electrode can also be used if necessary, via a regulating mechanism accommodated in thevoltage supply unit 4.

The regulating mechanism, which is installed in the voltage supply unit 4 and will not be described in greater detail, uses the current measured values obtained with the simulator electrode 5, including if appropriate the measured value ofconductivity, to regulate the voltage between the main and counter-electrodes 3 and 7 in such a way that a current density sufficient for an adequate scaring effect is basically maintained.

For some applications a simplified version of the simulator electrode is sufficient, which takes the form of an immersed wire or plate-type electrode. In this instance there is no adaptation to specific characteristic values of fish bodies.